小麦抗倒性研究进展

倒伏是严重影响小麦子粒产量和品质的一个重要因素。本文系统阐述了小麦茎秆形态和结构特性、茎秆化学成分与抗倒伏关系以及抗倒性的遗传和分子标记等方面的最新研究进展。株高、基部节间长度与抗倒性呈负相关;而基部节间粗度、秆壁厚、单位长度干重与抗倒性呈正相关。茎秆机械组织细胞层数、厚度,维管束数目、面积以及髓腔大小与抗倒性密切相关。茎秆化学成分中纤维素、木质素以及碳水化合物含量和硅、钾元素含量与抗倒性呈正相关。小麦抗倒性呈数量性状遗传特征,除受多对主基因控制外,可能还受微效修饰基因作用。采用分子标记技术已将抗倒性以及与抗倒性相关的茎秆形态性状进行了QTL定位。     

套作大豆苗期茎秆纤维素合成代谢与抗倒性的关系

为从茎秆强度的角度研究套作大豆苗期对荫蔽胁迫的响应及耐荫抗倒机制,采用耐荫性不同的3个大豆材料,在玉米大豆套作和单作两种种植模式下,对茎秆的纤维素、可溶性糖、蔗糖、淀粉含量及蔗糖代谢中关键酶活性以及茎秆抗折力、抗倒伏指数等进行测定,研究它们与套作大豆苗期倒伏的关系.套作大豆苗期倒伏严重,茎秆抗折力、抗倒伏指数、纤维素、可溶性糖、蔗糖、淀粉含量和相关酶活性均显著低于单作.不同大豆材料受套作荫蔽影响程度不同,强耐荫性大豆南豆12茎秆抗折力降低幅度最小,在套作环境下其茎秆抗折力、抗倒伏指数大,纤维素、可溶性糖、蔗糖、淀粉含量高,酶活性强.相关分析表明： 套作大豆苗期茎秆糖含量均与抗折力呈极显著正相关,与倒伏率呈极显著负相关;蔗糖含量与蔗糖磷酸合酶(SPS)、蔗糖合酶(SS)、中性转化酶(NI)活性呈极显著正相关,与酸性转化酶(AI)活性相关性不显著;纤维素含量与SPS、SS呈极显著正相关,与NI呈显著正相关,与AI相关性不显著.套作环境下,强耐荫性大豆苗期茎秆中较高的SPS、SS活性是其维持高蔗糖和纤维素含量的酶学基础,而高纤维素含量有利于提高茎秆强度,进而增强其抗倒伏能力.本研究应用玉米大豆套作种植系统,从苗期抗倒角度,探明了光环境对不同基因型大豆茎秆纤维素代谢的影响机制,为下一步筛选耐荫抗倒大豆品种提供了理论依据.     

多效唑防止水稻倒伏的原因剖析

水稻拔节前后施用多效唑能使节间缩短,茎秆高度和植株重心位置降低,下弯力距减小。同时,单位长度茎秆内物质积累,纤维素和木质素含量增加。茎壁厚度和机械组织厚度显著增加,木化程度和茎秆的机械强度加强。从而有明显的防倒效果。     

玉米茎秆细胞壁和组织构建对抗压强度的影响

耐密抗倒伏玉米品种是玉米育种的重要方向,探究影响玉米茎秆抗压强度的机制是培育玉米新品种的重要途径。本实验采用组织化学、显微观察的方法研究了10个玉米品种茎秆的形态结构、解剖特征和细胞壁的化学组成,并分析了这些变量之间的相关性,结果表明:茎的皮层/半径、厚壁组织比例、机械组织比例和纤维素含量、木质素含量与抗压强度呈极显著正相关关系;薄壁组织比例、茎长/茎粗、维管束个数与抗压强度呈极显著负相关关系。利用共线性诊断和逐步线性回归分析发现,影响茎秆抗压强度的主要因素为皮层/半径、机械组织比例、维管束个数、纤维素含量和木质素含量。利用通径分析进一步定量研究了这5个变量与抗压强度之间的直接作用和间接作用,明确了决定玉米茎秆抗压强度的主要因素为纤维素含量、木质素含量和单位面积维管束个数。本实验还建立了玉米茎微观结构与细胞壁化学构成的数学模型,为进一步揭示玉米茎微观力学形成机理提供了思路,进而为耐密抗倒伏玉米育种提供了研究方向。     

小麦种质抗倒性的评价和抗倒性状的相关与通径分析

对９６份小麦种质资源的抗倒性进行了鉴定评价,筛选出高抗型材料９份,其中４份是丰源,表明抗倒性能够与丰产性状很好地协调结合。对抗倒性状的相关分析表明,在株高相差较大的情况下,株高和重心高度对抗倒性十分重要。但在对株高相差不大的情况下,茎秆的机械强度是主要决定因素,对于株高较高的材料,重心高度对抗倒性有较大影响;对于较矮的材料,基部第一节间长度则较为重要。通径分析结果进一步表明,茎秆机械强度对抗倒性的     

水稻茎秆形态结构特征和化学成分与抗倒伏关系综述

水稻茎秆形态结构特征和化学成分与其抗倒伏性能相关。本文对水稻茎秆高度、茎秆基部第1、2节间长度、茎秆粗细、茎壁厚度、厚壁组织(机械组织)数量和强度、维管束数量、细胞壁纤维素和木质素含量、细胞中碳水化合物积累的数量、硅与钾的含量以及茎秆抗倒伏相关的QTL等与水稻的抗倒伏性的相互关系进行了综述,为水稻抗倒伏优良品种性状的选育提供参考。     

大田增强UV-B辐射对元阳梯田地方水稻茎秆性状和倒伏指数的影响

大田原位种植元阳梯田2个地方水稻品种——白脚老粳和月亮谷,研究2年不同强度(0、2.5、5.0和7.5 kJ·m^-2)UV-B辐射对水稻穗下第1至第4节的茎秆性状(节间长、茎秆粗和茎壁厚)和倒伏指数的影响.结果表明: 增强UV-B辐射对水稻茎秆的节间长和茎秆粗没有显著影响,但导致茎壁厚度显著减小,其中,7.5 kJ·m^-2 UV-B辐射对水稻穗下第4节茎秆茎壁厚度的影响较大,降幅为11.6%～19.6%;增强UV-B辐射导致水稻茎秆的倒伏指数增加,增大水稻倒伏的风险,水稻穗下第4节茎秆倒伏指数最大,并大于倒伏临界值(200);水稻穗下第4节、第3节和第2节茎秆的倒伏指数与茎壁厚度呈显著负相关.表明增强UV-B辐射显著减小元阳梯田水稻茎秆的茎壁厚是增加其倒伏风险的主要原因.
     

不同生态区小麦品种的穗发芽抗性评价

本研究对来自不同生态区的137个小麦品种进行穗发芽抗性鉴定,计算相对发芽指数,并分析这些品种穗部籽粒性状、品质指标、吸胀萌发后0～72 h α-淀粉酶活性及其基因表达量与穗发芽抗性之间的关系。结果表明: 长江中下游麦区小麦的平均发芽指数最低,抗穗发芽品种最多,其次是长江上游麦区,黄淮麦区抗穗发芽品种相对较少。红粒品种小麦的相对发芽指数低于白粒品种,相对发芽指数与籽粒长度、宽度呈极显著正相关,与小穗数呈显著正相关,与穗型、穗色、穗长、小穗密度、穗粒数、千粒重无显著相关性。相对发芽指数与容重呈极显著负相关,与面团形成时间和出粉率呈显著负相关,与蛋白质含量、湿面筋含量、吸水率、稳定时间、沉降值、拉伸面积、延展性、最大阻力无显著相关性。不同品种的α-淀粉酶活性随吸胀萌发时间的延长呈上升趋势,萌发24～72 h的相对发芽指数与α-淀粉酶活性呈极显著正相关,穗发芽中抗以上品种萌发48 h后α-淀粉酶活性聚类分析结果与穗发芽鉴定结果一致。萌发后各时段α-淀粉酶基因表达量与相对发芽指数呈极显著正相关。     

谷子抗倒伏性和株高、穗部性状的相关性研究

倒伏是限制作物产量提高的重要因素,而株高、穗长、穗粗、穗粒重等性状与产量密切相关,因此弄清抗倒伏性与这些性状的关系,对开展抗倒伏高产育种具有重要意义。本研究系统调查了41份谷子材料倒伏指数、株高、穗长、穗粗、穗码数、码粒数、穗粒重7个性状,结果表明：所有调查的7个性状指标在41份谷子材料中存在显著差异,除穗粗变异幅度较小,其余6个性状指标均存在丰富的遗传变异。相关性分析表明谷子基部第一、第二、第三节倒伏指数均与株高呈一定负相关,但未达到显著水平,与穗长、穗码数、码粒数、穗粒重均呈一定正相关,但只有第二节倒伏指数与穗长间的相关达到了显著水平（P<0.05）。倒伏指数与穗粗的相关性较复杂,第一、第三节倒伏指数与穗粗呈负相关,而第二节倒伏指数与穗粗呈正相关,但都未达到显著水平。株高与穗长、穗粗、穗码数、穗粒重4个产量关键性状间呈显著（P<0.05）或极显著（P<0.01）正相关;穗长、穗粗、穗码数、码粒数、穗粒重5个性状间呈极显著正相关（P<0.01）。研究结果认为在80 cm范围内,增加株高不会减弱谷子的抗倒伏性,谷子倒第二节抗倒伏性对整株植株抗倒伏性起到关键作用,应在抗倒伏高产育种中加以重视。     

玉米茎秆强度形成与木质素积累关系的研究

为探究玉米基部节间质量性状与茎秆强度形成的内在关系,该研究选用不同耐密性玉米品种为材料,采用随机区组设计,在田间条件下研究玉米基部节间形态特征、干物质积累的变化特点,分析茎秆内部木质素积累动态变化及其相关合成酶活性对茎秆强度形成的影响。结果表明：(1)耐密品种‘先玉335’基部节间单位长度干重(DWUL)和直径均较高,不同品种的茎秆强度快速形成时期有一定差异,与木质素的积累密切相关。(2)耐密品种茎秆穿刺强度(RPS)和木质素积累快速形成时期较不耐密品种‘新玉41’长5~7 d,穿刺强度高于不耐密品种24.9%~36.6%,其木质素积累量高于不耐密品种12.5%~47.0%,且RPS和木质素积累速率较不耐密品种快。(3)玉米抽雄期(VT)前是基部节间木质素快速积累的关键时期,玉米大喇叭口期(V12~V15)酶活性与抽雄期木质素积累量呈显著或极显著正相关,对茎秆强度形成至关重要。(4)在玉米12叶期耐密品种‘先玉335’的木质素合成相关酶均显著高于不耐密品种‘新玉41’,PAL、TAL、CAD和POD分别较‘新玉41’高1.85、0.30、0.11和0.42 U·mg^-1。研究认为,玉米大喇叭口期茎秆干物质积累量较高、木质素合成相关酶的活性较强,能有效促进木质素的快速积累,增加茎秆抗倒伏强度,进而提高玉米茎秆抗倒伏能力。     

Characterising the morphological characters and carbohydrate metabolism of oat culms and their association with lodging resistance

• Lodging resistance can be improved by enhancing the mechanical strength of culms, and culm carbohydrates could improve this mechanical strength. Culm carbohydrates can regulate development of the culm and affect its toughness.
• The present study determines the relationship between lodging and carbohydrate content in oat culms. Field experiments were conducted in alpine regions in 2017 and 2018 using three oat varieties with different lodging resistance. Lodging‐related morphological characteristics were directly determined and culm carbohydrate content and enzyme activity related to cellulose synthesis and sucrose metabolism were evaluated with ultraviolet spectrophotometry.
• Results showed that the lower the gravity height or the lower ratio of gravity height to plant height, the stronger the lodging resistance of the varieties. Higher culm nonstructural (NSC) and structural (SC) carbohydrate content contributed to the ability of culms to resist lodging, especially the content of cellulose and sucrose. PCA showed that sucrose metabolism and SC content were closely related to lodging resistance. Correlation analysis showed that the lodging index (LI) was significantly negatively correlated with NSC. Sucrose content was highly and significantly positively correlated with NSC. Additionally, the activities of sucrose phosphate synthase (SPS) and sucrose synthase (SS) were highly and significantly positively correlated with sucrose and cellulose content.
• The relationship between field characters and oat lodging, as well as the regulatory mechanism of carbohydrate content on lodging resistance of the culm are discussed.

     

Isolation,expression, and evolution analysis of the type 2C protein phosphatase gene <Emphasis Type="Italic">BcABI1</Emphasis> involved in abiotic and biotic stress in <Emphasis Type="Italic">Brassica campestris</Emphasis> ssp. <Emphasis Type="Italic">chinensis</Emphasis>

Dense plant cultivation is an efficient approach to utilize the maximum inputs for increasing maize production. However, dense plant populations may prone to lodging as it results in increased plant height and reduced culm diameter; therefore, we hypothesized that weaker stems may be responsible for maize lodging. In this study, we examined the regulatory effects of paclobutrazol under two commonly used application methods (seed-soaking and seed-dressing). Seed-soaking with paclobutrazol at the rate of 0 (CK1), 200 (S1), 300 (S2), and 400 (S3) mg L^?1, while seed-dressing at the rate of 0 (CK2), 1.5 (D1), 2.5 (D2), and 3.5 (D3) g kg^?1 were used. Results showed that paclobutrazol improved the culm physical strength by increasing the rind penetration strength, stalk breaking strength, culm diameter, wall thickness, and dry weight per unit length of basal third internode, compared to control plants. Moreover, paclobutrazol reduced the internode length, plant height, ear height, center of gravity height and lodging rate in both growing seasons. In addition, more lignin was accumulated in the basal internode and the activities of phenylalanine ammonia-lyase (PAL), peroxidase (POD), cinnamyl alcohol dehydrogenase (CAD) and 4-coumarate: CoA ligase (4CL) increased with paclobutrazol, and their maximum values were observed in the S2 and D3 treatments, resulting in strong lodging resistance. Lignin content was positively and significantly correlated with the rind penetration strength, breaking strength of internode, and activities of PAL, 4CL, POD, and CAD, while significantly and negatively correlated with lodging percentage. The present findings suggested that 300 mg L^?1 and 3.5 g kg^?1 of paclobutrazol may efficiently be utilized to minimize the risk of lodging, not only by manipulating plant height but also by enhancing culm physical strength and lignin accumulation in basal internodes.     

中国小麦主推品种和育成品系的抗倒伏性评价

倒伏是影响小麦产量的主要因素之一,选育抗倒伏性强的品种是育种研究的重点目标.本研究以528份我国主推的小麦品种和育成品系为材料,对影响小麦倒伏的主要性状进行测定,利用无偏线性估计值进行遗传变异分析、相关分析、主成分分析、线性回归分析和聚类分析,综合评价不同小麦品种的抗倒伏性.研究表明,6个抗倒伏性状在品种间都存在着广泛...     

小麦抗倒性状的基因效应及杂种优势分析

采用Ｈａｙｍａｎ双列分析较为系统地研究了抗倒性状的基因效应,并进行了杂种优势分析。结果表明,小麦抗倒性状的遗传以效应和显微效应为主,且以显著性效较为重要。     

水稻基部伸长节间性状与茎秆机械强度的相关分析和QTL定位

分析水稻品种‘沈农265’和‘丽江新团黑谷’杂交的F2群体基部第二节间茎秆机械强度与该节间形态和茎秆解剖结构的相关性,并对基部第二节间机械强度和相关性状进行QTL定位的结果表明：机械强度与茎粗、茎壁面积、茎壁厚度、大小维管束数目、大小维管束面积、大小维管束韧皮部面积、大小维管束木质部面积呈显著或极显著的正相关,与节间长度呈极显著的负相关,而与茎秆扁平率的相关不显著。采用复合区间作图,从研究的14个目标性状中检测到18个QTL。控制基部第二节间的抗折力的QTL检测到4个,位于第4、7、9和10号染色体上,可解释遗传变异的12%～23%。在第4和第7染色体上的相同区间上还同时检测到了控制茎壁性状和维管束性状QTL,贡献率在12%～21%之间。说明这两个位点是控制基部第二节间机械强度的重要区域,也是茎壁性状、维管束性状与机械强度高度正相关的遗传学基础。     

Nitrogen fertilizer application affects lodging resistance by altering secondary cell wall synthesis in japonica rice (<Emphasis Type="Italic">Oryza sativa</Emphasis>)

Stem mechanical strength is an important agricultural quantitative trait that is closely related to lodging resistance in rice, which is known to be reduced by fertilizer with higher levels of nitrogen. To understand the mechanism that regulates stem mechanical strength in response to nitrogen, we analysed stem morphology, anatomy, mechanical properties, cell wall components, and expression of cell wall-related genes, in two varieties of japonica rice, namely, Wuyunjing23 (lodging-resistant variety) and W3668 (lodging-susceptible variety). The results showed that higher nitrogen fertilizer increased the lodging index in both varieties due to a reduction in breaking strength and bending stress, and these changes were larger in W3668. Cellulose content decreased slightly under higher nitrogen fertilizer, whereas lignin content reduced remarkably. Histochemical staining revealed that high nitrogen application decreased lignin deposition in the secondary cell wall of the sclerenchyma cells and vascular bundle cells compared with the low nitrogen treatments, while it did not alter the pattern of cellulose deposition in these cells in both Wuyunjing23 and W3668. In addition, the expression of the genes involved in lignin biosynthesis, OsPAL, OsCoMT, Os4CL3, OsCCR, OsCAD2, OsCAD7, OsCesA4, and OsCesA7, were also down-regulated under higher nitrogen conditions at the early stage of culm growth. These results suggest that the genes involved in lignin biosynthesis are down-regulated by higher nitrogen fertilizer, which causes lignin deficiency in the secondary cell walls and the weakening of mechanical tissue structure. Subsequently, this results in these internodes with reduced mechanical strength and poor lodging resistance.